src/ir/layout.rs - third_party/github.com/rust-lang/rust-bindgen - Git at Google

 //! Intermediate representation for the physical layout of some type.

 use super::derive::CanDerive;
 use super::ty::{Type, TypeKind, RUST_DERIVE_IN_ARRAY_LIMIT};
 use crate::clang;
 use crate::ir::context::BindgenContext;
 use std::cmp;

 /// A type that represents the struct layout of a type.
 #[derive(Debug, Clone, Copy, PartialEq)]
 pub struct Layout {
     /// The size (in bytes) of this layout.
     pub size: usize,
     /// The alignment (in bytes) of this layout.
     pub align: usize,
     /// Whether this layout's members are packed or not.
     pub packed: bool,
 }

 #[test]
 fn test_layout_for_size() {
     use std::mem;

     let ptr_size = mem::size_of::<*mut ()>();
     assert_eq!(
         Layout::for_size_internal(ptr_size, ptr_size),
         Layout::new(ptr_size, ptr_size)
     );
     assert_eq!(
         Layout::for_size_internal(ptr_size, 3 * ptr_size),
         Layout::new(3 * ptr_size, ptr_size)
     );
 }

 impl Layout {
     /// Gets the integer type name for a given known size.
     pub fn known_type_for_size(
         ctx: &BindgenContext,
         size: usize,
     ) -> Option<&'static str> {
         Some(match size {
             16 if ctx.options().rust_features.i128_and_u128 => "u128",
             8 => "u64",
             4 => "u32",
             2 => "u16",
             1 => "u8",
             _ => return None,
         })
     }

     /// Construct a new `Layout` with the given `size` and `align`. It is not
     /// packed.
     pub fn new(size: usize, align: usize) -> Self {
         Layout {
             size,
             align,
             packed: false,
         }
     }

     fn for_size_internal(ptr_size: usize, size: usize) -> Self {
         let mut next_align = 2;
         while size % next_align == 0 && next_align <= ptr_size {
             next_align *= 2;
         }
         Layout {
             size: size,
             align: next_align / 2,
             packed: false,
         }
     }

     /// Creates a non-packed layout for a given size, trying to use the maximum
     /// alignment possible.
     pub fn for_size(ctx: &BindgenContext, size: usize) -> Self {
         Self::for_size_internal(ctx.target_pointer_size(), size)
     }

     /// Is this a zero-sized layout?
     pub fn is_zero(&self) -> bool {
         self.size == 0 && self.align == 0
     }

     /// Construct a zero-sized layout.
     pub fn zero() -> Self {
         Self::new(0, 0)
     }

     /// Get this layout as an opaque type.
     pub fn opaque(&self) -> Opaque {
         Opaque(*self)
     }
 }

 /// When we are treating a type as opaque, it is just a blob with a `Layout`.
 #[derive(Clone, Debug, PartialEq)]
 pub struct Opaque(pub Layout);

 impl Opaque {
     /// Construct a new opaque type from the given clang type.
     pub fn from_clang_ty(ty: &clang::Type, ctx: &BindgenContext) -> Type {
         let layout = Layout::new(ty.size(ctx), ty.align(ctx));
         let ty_kind = TypeKind::Opaque;
         let is_const = ty.is_const();
         Type::new(None, Some(layout), ty_kind, is_const)
     }

     /// Return the known rust type we should use to create a correctly-aligned
     /// field with this layout.
     pub fn known_rust_type_for_array(
         &self,
         ctx: &BindgenContext,
     ) -> Option<&'static str> {
         Layout::known_type_for_size(ctx, self.0.align)
     }

     /// Return the array size that an opaque type for this layout should have if
     /// we know the correct type for it, or `None` otherwise.
     pub fn array_size(&self, ctx: &BindgenContext) -> Option<usize> {
         if self.known_rust_type_for_array(ctx).is_some() {
             Some(self.0.size / cmp::max(self.0.align, 1))
         } else {
             None
         }
     }

     /// Return `true` if this opaque layout's array size will fit within the
     /// maximum number of array elements that Rust allows deriving traits
     /// with. Return `false` otherwise.
     pub fn array_size_within_derive_limit(
         &self,
         ctx: &BindgenContext,
     ) -> CanDerive {
         if self
             .array_size(ctx)
             .map_or(false, |size| size <= RUST_DERIVE_IN_ARRAY_LIMIT)
         {
             CanDerive::Yes
         } else {
             CanDerive::Manually
         }
     }
 }
	//! Intermediate representation for the physical layout of some type.

	use super::derive::CanDerive;
	use super::ty::{Type, TypeKind, RUST_DERIVE_IN_ARRAY_LIMIT};
	use crate::clang;
	use crate::ir::context::BindgenContext;
	use std::cmp;

	/// A type that represents the struct layout of a type.
	#[derive(Debug, Clone, Copy, PartialEq)]
	pub struct Layout {
	/// The size (in bytes) of this layout.
	pub size: usize,
	/// The alignment (in bytes) of this layout.
	pub align: usize,
	/// Whether this layout's members are packed or not.
	pub packed: bool,
	}

	#[test]
	fn test_layout_for_size() {
	use std::mem;

	let ptr_size = mem::size_of::<*mut ()>();
	assert_eq!(
	Layout::for_size_internal(ptr_size, ptr_size),
	Layout::new(ptr_size, ptr_size)
	);
	assert_eq!(
	Layout::for_size_internal(ptr_size, 3 * ptr_size),
	Layout::new(3 * ptr_size, ptr_size)
	);
	}

	impl Layout {
	/// Gets the integer type name for a given known size.
	pub fn known_type_for_size(
	ctx: &BindgenContext,
	size: usize,
	) -> Option<&'static str> {
	Some(match size {
	16 if ctx.options().rust_features.i128_and_u128 => "u128",
	8 => "u64",
	4 => "u32",
	2 => "u16",
	1 => "u8",
	_ => return None,
	})
	}

	/// Construct a new `Layout` with the given `size` and `align`. It is not
	/// packed.
	pub fn new(size: usize, align: usize) -> Self {
	Layout {
	size,
	align,
	packed: false,
	}
	}

	fn for_size_internal(ptr_size: usize, size: usize) -> Self {
	let mut next_align = 2;
	while size % next_align == 0 && next_align <= ptr_size {
	next_align *= 2;
	}
	Layout {
	size: size,
	align: next_align / 2,
	packed: false,
	}
	}

	/// Creates a non-packed layout for a given size, trying to use the maximum
	/// alignment possible.
	pub fn for_size(ctx: &BindgenContext, size: usize) -> Self {
	Self::for_size_internal(ctx.target_pointer_size(), size)
	}

	/// Is this a zero-sized layout?
	pub fn is_zero(&self) -> bool {
	self.size == 0 && self.align == 0
	}

	/// Construct a zero-sized layout.
	pub fn zero() -> Self {
	Self::new(0, 0)
	}

	/// Get this layout as an opaque type.
	pub fn opaque(&self) -> Opaque {
	Opaque(*self)
	}
	}

	/// When we are treating a type as opaque, it is just a blob with a `Layout`.
	#[derive(Clone, Debug, PartialEq)]
	pub struct Opaque(pub Layout);

	impl Opaque {
	/// Construct a new opaque type from the given clang type.
	pub fn from_clang_ty(ty: &clang::Type, ctx: &BindgenContext) -> Type {
	let layout = Layout::new(ty.size(ctx), ty.align(ctx));
	let ty_kind = TypeKind::Opaque;
	let is_const = ty.is_const();
	Type::new(None, Some(layout), ty_kind, is_const)
	}

	/// Return the known rust type we should use to create a correctly-aligned
	/// field with this layout.
	pub fn known_rust_type_for_array(
	&self,
	ctx: &BindgenContext,
	) -> Option<&'static str> {
	Layout::known_type_for_size(ctx, self.0.align)
	}

	/// Return the array size that an opaque type for this layout should have if
	/// we know the correct type for it, or `None` otherwise.
	pub fn array_size(&self, ctx: &BindgenContext) -> Option<usize> {
	if self.known_rust_type_for_array(ctx).is_some() {
	Some(self.0.size / cmp::max(self.0.align, 1))
	} else {
	None
	}
	}

	/// Return `true` if this opaque layout's array size will fit within the
	/// maximum number of array elements that Rust allows deriving traits
	/// with. Return `false` otherwise.
	pub fn array_size_within_derive_limit(
	&self,
	ctx: &BindgenContext,
	) -> CanDerive {
	if self
	.array_size(ctx)
	.map_or(false, \|size\| size <= RUST_DERIVE_IN_ARRAY_LIMIT)
	{
	CanDerive::Yes
	} else {
	CanDerive::Manually
	}
	}
	}